Observation of magnetically-induced transition intensity redistribution in the onset of the hyperfine Paschen-Back regime

Abstract

The Zeeman effect is an important topic in atomic spectroscopy. The induced change in transition frequencies and amplitudes finds applications in the Earth-field-range magnetometry. At intermediate magnetic field amplitude B B0 = Ahfs/μB, where Ahfs is the magnetic dipole constant of the ground state, and μB is the Bohr magneton (B0≈ 1.7 kG for Cs), the rigorous rule F = 0, 1 is affected by the coupling between magnetic sub-levels induced by the field. Transitions satisfying F = 2, referred to as magnetically-induced transitions, can be observed. Here, we show that a significant redistribution of the Cs 6S1/2→ 6P3/2 magnetically-induced transition intensities occurs with increasing magnetic field. We observe that the strongest transition in the group Fg=3→ Fe=5 (σ+ polarization) for B<B0 cease to be the strongest for B>3 B0. On the other hand, the strongest transition in the group Fg=2→ Fe=4 (σ- polarization) remains so for all our measurements with magnetic fields up to 9 kG. These results are in agreement with a theoretical model. The model predicts that similar observations can be made for all alkali metals, including Na, K and Rb atoms. Our findings are important for magnetometers utilizing the Zeeman effect above Earth field, following the rapid development of micro-machined vapor-cell-based sensors.

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